RU2183741C1 - Method of gas-hydraulic stimulation of formation - Google Patents

Abstract

FIELD: means for oil production. SUBSTANCE: method includes performance of deep perforation of all intervals of treated formation, assembly of bulky sectional charge with central channel. Equipment components are passed through said central channel. Charge is run into well and its sections are burnt. Charge sections are made of compositions ensuring their burning in water, water-oil and acid media with formation of gaseous combustion products, increase of pressure and temperature. Control of burning of charge sections is carried out in regime of real time in rapidly proceeding burning process. Regime of charge operation characteristics is recorded. Character of action on formation and response of bottom-hole zone to stimulation are judged by character of variation of charge operation characteristics. For assembly of charge, use is made of sectional rod. Rod is made of material allowing preservation of its integrity under mechanical and heat loads during lowering and lifting and burning of charge. Rod has a hollow channel passing inside it along central axis for accommodating of wire supplying the ignition unit with power and wire with heat-resistant insulation connecting logging cable with electronic unit for control and recording of characteristics of charge operation conditions. It is connected to rod lower end spaced from charge section at such distance that hot gaseous combustion products of charge do not affect it. To reduce load on rod and provision of formation stimulation, dissipator of gaseous flow is located between charge lower section and electronic unit. EFFECT: provision of formation fracturing for increasing reliability of hydrodynamic communication. 2 cl, 1 dwg

Description

 The invention relates to means for oil production.

 One of the rational and effective methods of influencing the borehole zone of a productive formation in order to establish a reliable hydrodynamic connection between a well and a formation is gas-hydraulic treatment of the formation with powder combustion products. Under the influence of liquid and gas pressure equal to or greater than the rock, rocks are irreversibly deformed. The method of gas-hydraulic exposure to powder gases is based on the mechanical, thermal and chemical effects of gases on rocks and their saturating fluids. To use the method used powder generators pressure PGD. BK-100 M, PGD. BK-150 and pressure accumulators ADS-5 [1].

 There is a method of gas-hydraulic stimulation of a formation by using a sectional powder pressure generator to ensure its combustion on the inner surface, for which the generator charges are coated with a protective coating [2]. When an electrical impulse is applied through the cable, igniters of charges are ignited. The resulting combustion products of the powder charges affect the reservoir.

 Using this method does not always give a positive effect. This is due to the fact that the protective coating, the connecting nodes of the charges and accessories remain in the well. With a small depth of the bottom from the perforation zone, additional cleaning of the well is necessary for re-opening the formation. There is a cable overlap. During the charge burning, the liquid column rises by 15-20 m, which can lead to the destruction of the casing string due to the pressure drop in the well and annulus exceeding its strength.

 As the closest analogue, the method of gas-hydraulic stimulation of the formation is adopted, which includes deep-perforating perforation at all intervals of the treated formation, assembling an unpacked sectional charge by passing parts of the tooling to collect charge sections through the central channel of each charge section and pulling them close to each other by other equipment parts , descent of the charge into the well and burning of its sections made of compositions providing combustion in an aqueous, oil-water and acidic environment, p then start the ignition unit and the subsequent ignition of one or more igniter sections of the charge and the main sections of the charge with the formation of combustion products, increasing pressure and temperature [3]. In the ignition section of the charge, the diameter of the channel is larger than in the main sections. As the ignition section of the charge, a support tube with pyrotechnic igniters is used, in the upper part it is sealed with a cable head, to which a geophysical cable is attached with two main sections of the charge attached to it with an upper tip, and in the lower part there is a sealed plug with a cable attached to it , close to the igniter section, put on three main sections of the charge. The device is lowered into the well and installed above the perforation interval by 2-4 m. The igniters are ignited, which burn through the walls of the pipes and ignite the ignition section of the charge, and from it the main sections of the charge. Charge burning occurs from the channel. The lateral surface of the charge has a protective coating that protects the charge from friction and impact on the column.

 The application of this method does not always give a positive effect. This is due to the fact that the charges are collected on a geophysical cable, at the junction of the charges during their burning, overheating and rupture of the wireline cable occur, the charge sections are disconnected, which can lead to an emergency, in addition, it has all the drawbacks of the previous analogue. Setting the charge in the borehole above the perforation interval leads to the fact that the pressure of the borehole fluid, to which the energy of the gases is transmitted, acts on the treated formation.

 The technical result of the invention is the creation of cracks and cavities in the near-wellbore zone of the treated formation, which provide reliable hydrodynamic communication with the remote zone of the formation, which has natural filtration properties, i.e. fracture.

 The required technical result is achieved by the fact that in the method of gas-hydraulic treatment of the formation, which includes deep-perforating perforations at all intervals of the treated formation, assembly of an open-section sectional charge with a central channel through which tooling parts are passed, charge discharge into the well and burning sections made of compositions providing combustion in an aqueous, oil-water and acidic environment, with the formation of gaseous products of combustion, increasing pressure and temperature, according to In the process of quick combustion processes, the combustion of the charge sections is monitored in real time, the characteristics of the charge mode are recorded and the nature of their changes is used to determine the nature of the effect on the formation and the reaction of the bottom-hole zone to the effect, for which a composite rod made of material is used to assemble the charge , allowing to maintain integrity under the influence of mechanical and thermal loads during the descent of the charge and its burning, with a hollow channel passing inside the rod along its central axis to pass the ignition unit power supply wire and heat-resistant insulation wire connecting the logging cable to the electronic unit for monitoring and recording the characteristics of the charge mode, which is connected to the lower end of the rod and is located at a distance from the charge sections so that hot gaseous products of combustion charge did not have a direct impact on him, while to reduce the load on the rod and ensure maximum directional impact on the treated formation, between The bottom of the charge section and the electronic unit have a gas flow diffuser.

 In addition, the formation is fractured, for which several successive operations are performed on the formation — assembling and lowering the charge and burning the charge sections in the same interval of the formation and lifting the rig from the well with an attached electronic unit for monitoring and recording the characteristics of the charge operation mode , the mass of charge sections during the first combustion is chosen so as to provide a pressure in the interval of the treated formation that exceeds the tensile strength of the rocks composing the formation to create cracks in the formation and both sintering reliable hydrodynamic connection between the well and the formation, they monitor the combustion of the charge sections in real time, then snap up from the well, according to the recorded curves of the characteristics of the charge mode, the bottom-hole zone is affected by the impact, the mass of the charge is determined for the subsequent action to ensure in the interval of the treated formation, the pressure is sufficient to develop and deepen the cracks formed during the first burning of the charge sections and the creation of cavities inside the cavity and, changing the length of the composite rod, carried consequent impact on the character formation for the change curve during combustion of the charge sections and their change during the first and subsequent combustion is judged on the nature of the stimulation and the effect of bottomhole reaction zone.

 For clarity, the method is illustrated in the drawing, which shows a device for gas-hydraulic impact on the reservoir. The device includes an ignition unit 1, an ignition section of a charge 2, a main section of a charge 3, a groove for installing an ignition unit 4, a composite rod 5, an integral bearing part of a rod 6, connecting parts of a rod 7, 8, a gas flow diffuser 9, a linear expansion compensator for charge sections 10, wireline cable 11, electronic unit for monitoring and recording the characteristics of the charge mode 12, upper and lower centralizers 13, power cable of the ignition unit 14, wire with heat-resistant insulation 15 connecting the wireline spruce with an electronic control unit and recording the characteristics of the charge mode.

 An example implementation of the method. Conduct deep penetration perforation at all intervals of the reservoir. Then carry out the assembly of the open sectional charge with the ignition unit 1, one or more ignition sections 2 and the main sections of the charge 3. The charge is assembled. To do this, use a composite rod 5 (composed of several elements). The rod consists of a composite supporting part 6 and connecting parts 7 and 8. Using a composite rod allows you to collect a charge from a different number of sections and simplify the delivery of the rod to the well. The mass of the burned charge sections is calculated. It should be sufficient to provide in the interval of the treated formation a pressure exceeding the tensile strength of the rocks composing the formation by 1.5 times. The charge sections are the same in size and weight, therefore, knowing the charge mass, the number of charge sections and the length of the component bearing part of the rod are determined 6. The component bearing part of the rod is passed through the central channel of each charge section, through the linear expansion of charge 10 to elasticly compress the charge sections at high temperatures in the well and the gas stream diffuser 9. The sum of the bore holes of the diffuser holes is calculated so as to reduce the load on the rod and ensure maximum directional impact on the formation. The upper 7 and lower 8 connecting parts of the rod are connected to both ends of the component supporting part of the rod 6. The upper part of the upper connecting rod 7 is connected via a cable lug to the wireline cable 11, and the lower one to the electronic unit for monitoring and recording the characteristics of the charge mode 12.

 The connection of the upper 7 and lower 8 of the connecting parts of the rod with the integral bearing part 6 of the rod is carried out by centralizers 13, which are also designed to constrain the powder sections of the charge, to prevent them from moving relative to the bearing part of the rod during descent and burning of the charge. They are made in a streamlined shape that ensures minimal upward and downward turbulence during charge burning, with a diameter greater than the diameter of the charge sections so that the charge sections do not touch the walls of the casing.

 The composite rod 5 is made with a hollow channel extending inside the rod along its central axis to pass the ignition unit power wire and heat-resistant insulation wire connecting the wireline cable to the electronic unit for monitoring and recording the characteristics of the charge mode, which is connected to the lower end of the rod and is located from sections of the charge at such a distance that the hot gaseous products of the combustion of the charge did not directly affect it.

 The charge is lowered into the well and installed so that the charge sections are opposite the perforation holes and the gaseous products of combustion of the charge sections directly affect the treated formation. For depth reference, a clutch locator located in the electronic unit 12 is used. Upon the operator’s command from the ground panel, the device is started by supplying electric current through the wireline 11, through the power supply cable 14 of the ignition unit to the spiral of the ignition unit 1, and by wire 15 to the electronic unit 12. At a coil heating temperature exceeding the flash point of the charge, the ignition powder section 2 (one or more) ignites, from it are the main sections of charge 3 adjacent to it, from which the remaining ignition nye basic charge section. Because the charge sections do not have a protective coating, therefore, the charge is burned over the entire surface of the charge. The configuration of the central channel is adopted with a developed surface. All this ensures the burning time of the charge sections is shorter than the propagation time of the compression wave through the borehole fluid from the exposure interval to the wellhead. When the charge is burning, a large amount of hot gases is formed, which through the diffuser 9 enter the casing and directly affect the formation being processed through the perforations. Since the burning time of the charge sections is fractions of a second, a pulse effect of gases with high temperature and pressure is carried out. When the charge is burning, a large amount of hot gases is formed, which fill the casing. In the interval of its location, temperature, pressure rises, and high-temperature gas flows move. The power wire of the ignition unit 14 and the wire 15 from the geophysical cable pass through the inner cavity of the rod. This protects them from mechanical damage in the well, direct exposure to hot powder gases.

 Monitoring the operation of the device and evaluating its impact on the formation is carried out using continuous recording schedules for recording the parameters of the charge in time (temperature, pressure, vibroacoustic parameters, etc.).

 They control the burning of the charge sections in real time. After that, the equipment and the electronic unit are lifted from the well, visual inspection is carried out, according to the recorded curves of the characteristics of the charge operating mode, they are judged on the reaction of the bottom-hole zone to the effect. The mass of charge sections is calculated for subsequent exposure such that, when they are burned in the well, a gas inlet capable of creating a design pressure that is 1.8 times higher than the mountain pressure is sufficient to develop and deepen the cracks formed during the first operation and creating cavities inside the formation. Knowing the mass, determine the number of sections and the length of the component bearing part of the rod. The length of the component supporting part of the rod is changed, the charge is assembled, the charge is lowered into the well at the same interval and the charge sections are burned. The repeated pulsed action of gases with high temperature and pressure leads to the development of cracks, the creation of cavities inside the formation, i.e. carry out fracturing. If after the second operation the formation has not been fractured, then a subsequent operation is carried out.

 Thus, the proposed method allows for gas-dynamic impact with a fracture, without violating the integrity of the casing and cement stone. The application of the proposed charge snap provides charge strength under mechanical and thermal loads. In addition, the equipment does not remain in the well, but can be reused.

 Using the electronic unit for monitoring and recording the characteristics of the charge operating mode allows you to control the operation of the device, the burning time of the charge, to evaluate its effect on the formation. Since the electronic unit is placed below the treated formation, it is less affected by upward gas flows. No cable overlap. Since the electronic unit is attached to the rod, which allows maintaining integrity under the influence of mechanical and thermal loads, for example, metal, and not on the wireline cable, the probability of its breakage is reduced. Since the wires from the logging cable to the electronic unit to the ignition unit pass through the internal cavity of the charge, they are protected from mechanical and thermal influences.

 The use of this device has been tested in wells. As a result, the wells produced additional oil production. For the first time, real-time characteristics of the charge on the well were obtained. After the work, the measuring unit, equipment were lifted from the well and after verification they were used on another well.

List of references
1. Shooting and explosive equipment. Reference book / L.Ya. Fridlander, V.A. Afanasyev, L.S. Vorobiev et al. Ed. L.Ya. Friedlander, 2nd ed. Re-worker. and add. - M .: Nedra, 1990. Section 4. Powder generators and pressure accumulators, p.107-108.

 2. Shooting and explosive equipment. Reference book / L.Ya. Fridlander, V.A. Afanasyev, L.S. Vorobiev et al. Ed. L.Ya. Fridlyander, 2nd ed. Re-worker. and add. - M .: Nedra, 1990. Section 4.1. Powder pressure generators, p. 108.

 3. Shooting and explosive equipment. Reference book / L.Ya. Fridlander, V.A. Afanasyev, L.S. Vorobiev et al. Ed. L.Ya. Friedlander, 2nd ed. Re-worker. and add. M .: Nedra, 1990. Section 4.1. Powder pressure generators, pp. 109-112.

Claims (2)

 1. A method of gas-hydraulic treatment of a formation, including deep-perforating perforations at all intervals of the treated formation, assembly of an open-section sectional charge with a central channel through which tooling parts are passed, charge is lowered into the well and its sections are made from compositions that provide combustion in water water-oil and acidic environment, with the formation of gaseous products of combustion, an increase in pressure and temperature, characterized in that with fast-flowing processes of burning wasps They monitor the burning of the charge sections in real time, record the characteristics of the charge operating mode and determine the nature of the impact on the formation and the reaction of the bottom-hole zone to the effect, for which a composite rod made of a material is used to assemble the charge, which allows maintaining integrity at mechanical and thermal loads during the descent, rise of the charge and its burning, with a hollow channel passing inside the rod along its central axis to pass the power supply ignition lines and wires with heat-resistant insulation, connecting the logging cable to the electronic control unit, and recording the characteristics of the charge operating mode, which is connected to the lower end of the rod and located at such a distance from the charge sections that hot gaseous products of charge combustion do not directly affect it at the same time, to reduce the load on the rod and ensure maximum directed action on the treated formation, between the lower charge section and the electronic unit are placed scatterer gas stream.  2. The method according to p. 1, characterized in that the fracturing is carried out, for which several sequential operations are performed on the reservoir - assembling and lowering the charge and burning the charge sections in the same interval of the reservoir and lifting the rig with the rig attached to it the electronic unit for monitoring and recording the characteristics of the charge operating mode, the mass of the charge sections during the first combustion is chosen so as to provide in the interval of the treated formation a pressure exceeding the tensile strength of the rocks composing the formation to create formation of cracks in the formation and ensuring reliable hydrodynamic connection between the well and the formation, they control the burning of the charge sections in real time, then they snap up from the well, according to the recorded curves of the characteristics of the mode of charge operation, they are judged about the reaction of the bottomhole zone to the impact, the charge mass is determined for the subsequent such exposure to provide sufficient pressure in the interval of the treated formation to develop and deepen the cracks formed during the first burning of the charge sections, and create of the cavities inside the formation, change the length of the composite rod, carry out the subsequent impact on the formation, and the nature of the impact on the formation and the reaction of the bottom-hole zone to the impact are judged by the nature of the changes in the recorded curves during the combustion of the charge sections and their changes during the first and subsequent burns .

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